Optical vend-sensing system for control of vending machine

ABSTRACT

A light curtain device for use in a vending machine which has at least one mechanism arranged for initiating operation upon selection by a customer for vending an article into a vend space through which the article falls into a customer-accessible hopper. The light curtain device has first and second emitter/detector arrays, each comprising at least one emitter and a plurality of detectors, said arrays being positionable and arrangeable within said vending machine so that electromagnetic radiation emitted by said at least one emitter of said first array may be detected by at least some of said plurality of detectors of said second array, and so that electromagnetic radiation emitted by said at least one emitter of said second array may be detected by at least some of said plurality of detectors of said first array, and so that articles falling through the vend space of the vending machine will interrupt electromagnetic radiation between at least one emitter and at least one detector.

RELATED APPLICATIONS

This application is related to and claims priority from U.S. Provisional Patent application No. 60/586,298, titled “Optical Vend-Sensing System For Control Of Vending Machine,” filed Jul. 9, 2004, the contents of which are incorporated herein by reference.

FIELD OF THE INVENTION

This invention relates to a machine that dispenses objects and detects the dispensed objects with an optical sensor. More particularly, this invention relates to an optical vend-sensing system and a vending machine that has an optical vend-sensing system.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention is better understood by reading the following detailed description with reference to the accompanying drawings in which:

FIGS. 1-7 depict detector mechanisms according to embodiments of the present invention.

DETAILED DESCRIPTION OF THE PRESENTLY PREFERRED EXEMPLARY EMBODIMENTS BACKGROUND

In a typical glass-front vending machine, the user of the machine sees a glass-fronted cabinet, with a selector panel located off to one side of the glass. Through the glass, there can be seen an array of articles, typically packaged snack foods arranged in horizontal columns which extend horizontally in a front-to-rear depthwise direction, with a plurality of columns at each of several vertically spaced levels. At each level the articles are pocketed in-between adjacent turns of respective spirals arranged one or two to a column. Each spiral has an axially central rearwardly projecting stem at its rear, which is plugged into the chuck of a respective motor assembly mounted to the rear of a tray. When a user makes the requisite payment to the machine and makes a desired selection on the selector panel, the spiral or spirals for the respective column begin to turn causing all of the packaged articles received among the spiral turns in that column to advance. If the vending machine is working properly, the respective spiral or spirals turn sufficiently to cause the leading packaged article in the respective column to be conveyed sufficiently far forwards that the package loses support provided from underneath by a respective tray, and tumbles down past the front of the respective shelf, through a vend space between the fronts of the columns and the back of the glass front, into an outlet bin, from which the user can retrieve it, typically by temporarily pushing in a hinged from above, normally closed door.

Again, if the machine is working properly, the respective spiral or spirals cease being turned by the respective motor assembly before the next-in-line, newly leading package in the respective column mistakenly becomes conveyed so far forwards that it, too, falls off the tray, down through the vend space and becomes vended without a requisite payment having been made.

Several different unplanned occurrences can occur, and the possibility and likelihood of their occurrence complicates the design of glass-front vending machines.

It is important that users, upon making requisite payment, be reliably vended the product which they have selected, without any deficiency or bonus, and without any need, or apparent desirability for expending unusual effort, or that the user automatically be provided a return of payment, or the opportunity to make another selection.

Spatial orientation of packages and wrinkling of packaging, unusual distribution of contents of a package, unusual tumbling of a package through the vend space, an empty pocket in a spiral and similar factors all can cause mis-vending, particularly if the machine is one in which a spiral is made to turn through only a predetermined angular distance for vending a selected product, or the package being vended, depending on how it falls, can bypass a detector meant to terminate rotation of the respective spiral or spirals upon detecting that a package has been vended.

Many glass-front vendors are modularly constructed, so that the number of vertically-spaced rows of product columns, and/or the number of laterally spaced columns per row can be changed either at the time the machine is ordered by its purchaser, or in the field, or both. This fact also complicates provision of reliable vending, particularly if adding and deleting columns necessitates adding and deleting sensors and making sure that the sensors are properly positioned and correctly operating. Addition of sensors also adds to expense.

U.S. Pat. No. 6,384,402, and U.S. Pat. No. 6,794,634, which claims priority thereto, both assigned to the assignee of the present application and both of which are incorporated by reference herein, disclose optical vend sensing systems that are designed to provide an improved vend sensing system.

DESCRIPTION

The present invention includes several embodiments of an optical vend sensing system that are particularly adapted for use in a glass front vending machine, e.g., of the type disclosed in U.S. Pat. No. 6,384,402, although the present invention can also be used in other types of machines. In the example of a glass front vending machine, the optical vend sensing system is preferably positioned in the machine to detect articles which pass through the vend space.

FIG. 1 shows two emitter/detector arrays, each having a single optical emitter 14 and a plurality of detectors 16, generally positioned in a straight row, although other arrangements can be used. In some preferred embodiments, the emitter/detector arrays are mounted on circuit boards 10 and 12, which are preferably identical and can be merely reversed for installation opposite each other. An alternate number of emitters and detectors can be used on each board. For example, in some presently preferred embodiments, each array has one or two emitters (which may be adjacent) and between twelve and fourteen detectors. In some embodiments, the two (or more) emitters are on one end of the array. In some embodiments, there is at least one emitter on one end of the array, and at least one other emitter on the other end of the array, with the plurality of detectors being positioned between them.

The positioning of the emitters and detectors can also be altered. For instance, the emitter does not have to be at the end of each array, as shown in FIG. 1, but can be positioned somewhere in the middle of the array, as shown, for example, the configuration depicted in FIG. 2. However, positioning the emitters on the ends of the arrays minimizes dead spots in the sensed area.

Those of skill in the art will realize that the relative spacing of the emitters and detectors on an emitter/detector array depends on the number of emitters and/or detectors and on how far apart the arrays are to be spaced and on the expected size of articles to be vended.

In some presently preferred embodiments, each array has fourteen (14) detectors spaced approximately 0.45 inches apart and one emitter (at the end). The emitter is not spaced 0.45 inches from its closest detector.

During operation, each emitter 14 is energized (either constantly or pulsed) and the opposing detectors 16 are checked to determine if they are receiving light from the opposing emitter 14. The detectors may be checked one at a time (sequentially or in any order) or simultaneously or in groups. The emitters/detector arrays need not be mounted to a circuit board but can be positioned and connected to the vending machine in other manners.

FIG. 2 shows an embodiment of the present invention that uses one emitter 14 on one side and a plurality of detectors 16 on an opposing side. The emitter 14 is energized (either constantly or pulsed) and each detector 16 is checked to see if it received or is receiving light or is not because a vended object is obstructing the light. Again, the detectors may be checked one at a time (sequentially or in any order) or simultaneously or in groups.

FIG. 3 shows an embodiment of the present invention in which a plurality of detectors 16 are positioned, e.g., on a circuit board 18, in a stationary manner (FIG. 3A) while an emitter 14 is mounted on an oscillating pendulum arm 20 (FIG. 3B). In some embodiments, the arm 20 is mounted to shaft 22. Some mechanism such as, e.g., a motor 24, is used to cause the arm to oscillate. Instead of a motor 24, an electromagnet in combination with a spring art may be used to produce the required oscillation. Regardless of the mechanism, the emitter 14 is driven along an arc in an oscillating manner. The detectors 16 may be mounted on a circuit board or on some other location. In operation, the detectors 16 are checked to determine if there is an obstruction between the emitter and one or more detectors. In some embodiments, the detectors can be positioned in an arc corresponding to the arc of the emitter, although this is not required and they can be mounted in a straight line or other geometry. The range and speed of oscillation of the emitter can be varied as desired, but in a preferred manner, the arc of oscillation will span or substantially span the vend space. This embodiment could also be reversed with one or more fixed emitters and an oscillating detector. In one embodiment, the base drives the pendulum arm via use of an electromagnet and spring arm.

FIG. 4 shows an embodiment where an emitter 14 and detector 18 are mounted on opposing wheels 26 and 32, respectively, both of which move. The movement of the wheels can be a rotary movement or an oscillating movement. They can move in unison to maintain their relative positions to one another or move independently of one another. Each wheel (26, 32) could have multiple emitters and/or detectors and each could be functional for only a portion of the cycle. One reason to have the emitter/detector non-functional for part of their cycle is that there may be obstructions (such as the delivery bin) for part of the cycle. In such as this case, two emitters can be mounted on one wheel (e.g., 180 degrees apart) and two detectors can be mounted on the other wheel (e.g., 180 degrees apart). The processor then can simply ignore a signal from the detector for the part of the cycle when the emitter/detector pair is obstructed by the bin. During this time, the processor would consider the signal from the other emitter/detector pair as valid. Of course, more than two emitters and/or detectors can be used and each wheel can have both emitters and detectors (not just one or the other). The movement of the wheels 26 and 32 can be maintained with respect to one another by interconnecting the wheels with a shaft 34. In such cases, one motor 24 can drive both wheels. Alternatively, the separate wheels can be driven by separate motors and electronically controlled to move together. In one embodiment, the emitter(s) and detector(s) can rotate in opposite directions. This can be through a geared arrangement or can be accomplished via use of separate driving motors. The speed of movement can be set as desired but should be set fast enough to detect a product falling through the vend space. Each wheel can be moving at a different speed.

FIG. 5 shows an embodiment combining features of the embodiments shown in FIGS. 3 and 4. In this embodiment, the detector 14, mounted on pendulum arm 22 of base of motor 24, is rotated on one side and a plurality of detectors 16 are fixed on the other side. Alternatively, the detector(s) can move and the emitter(s) be fixed.

FIG. 6 shows an embodiment similar to that of FIG. 5, but with the emitter 14 mounted on a rotating (or oscillating) wheel 26. Alternatively, the detector(s) can move and the emitter(s) be fixed.

FIG. 7 shows an embodiment similar to that of FIG. 4 but with the emitter 14 and detector 16 mounted on rotating or oscillating pendulum arms 22 and 28, respectively.

Within a vending machine, the positioning of the emitter/detector units can be below the article vending units. For instance, in one embodiment, the emitter and detector units substantially extend a depth, front to rear of the machine, of the area through which vended products naturally fall. Other placements can also be used. For instance, the system shown in FIG. 2 could be adapted and arranged such that the emitter is mounted to the top inside door of the vendor and the detector(s) mounted to the bottom inside of the door.

In preferred versions of the embodiments disclosed herein, the emitters are not operated in a multiplexed manner.

In each of the embodiments disclosed above, the emitting of the signals and detecting of the emitted signals can be controlled through a CPU or other processing circuitry, hardware or software to detect an interruption of light from the detector(s) to the emitter(s) corresponding to a product falling through the vend space.

A logic circuit can be used with the detectors which allows conclusion of a vend on a detected occlusion of light to the detector of up to 100% of the corresponding light emitted. For instance, the logic circuit can be set to allow conclusion of the vend if the occlusion of light is in the range of 50-100% of the emitted light, or even less under certain circumstances.

The spacing between the detectors can be set as desired to provide a desired balance between more accurate sensing (i.e., closer spacing, thus requiring more detectors) and cost (i.e., larger spacing, requiring fewer detectors). Generally, the closer the spacing of the detectors, the more likely that an article dropping past the detectors will block a high percentage of the emitted light received by one or more of the detectors to more accurately sense a vend.

Where at least two emitters are used, with corresponding detectors positioned to receive the emitted light, the light of the different emitters can be pulsed at different frequencies and the detectors set to detect/signal only the light received at the pulsed frequency corresponding to the counterpart emitter. This can provide more accurate sensing by limiting consideration of emitted light not corresponding to the emitter(s) paired with the detector(s).

The light emitters and detectors may be of any type, though infrared emitters and detectors are preferable.

It is intended that various aspects of the different embodiments can be combined in different manners to create new embodiments.

While the invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not to be limited to the disclosed embodiment, but on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. 

1. In a vending machine which has at least one mechanism arranged for initiating operation upon selection by a customer for vending an article into a vend space through which the article falls into a customer-accessible hopper, an optical vend-sensing system comprising: (A) an article sensing subsystem arranged athwart said vend space, said article sensing subsystem comprising: (a1) a first emitter/detector array comprising at least one emitter and a plurality of detectors, and (a2) a second emitter/detector array comprising at least one emitter and a plurality of detectors, said first and second emitter/detector arrays positioned and arranged so that electromagnetic radiation emitted by said at least one emitter of said first array may be detected by at least some of said plurality of detectors of said second array, and so that electromagnetic radiation emitted by said at least one emitter of said second array may be detected by at least some of said plurality of detectors of said first array, and so that articles falling through the vend space will interrupt electromagnetic radiation between at least one emitter and at least one detector; (B) a machine control unit arranged to control operation of the respective at least one mechanism; and (C) control circuitry operatively connecting said article sensing subsystem with said machine control unit, and arranged to cause the machine control unit to complete a vend operation procedure of said at least one mechanism upon said article sensing subsystem sensing a transition of an article through said article sensing subsystem.
 2. An optical vend-sensing system as in claim 1, wherein the each of the first and second arrays comprises a single emitter and at least six detectors.
 3. An optical vend-sensing system as in claim 1, wherein the each of the first and second arrays comprises 1 to 2 emitters and 12 to 14 detectors.
 4. An optical vend-sensing system as in claim 1, wherein said emitter/detector arrays are arranged so that the at least one emitter of said first array is diagonally opposite the at least one emitter of said second array.
 5. An optical vend-sensing system as in claim 1, wherein the article sensing subsystem senses the transition of an article through said article sensing subsystem by determining that electromagnetic radiation reaching at least one detector as a result of electromagnetic radiation emission by said at least one emitter, has temporarily diminished by predetermined amount.
 6. In a vending machine which has at least one mechanism arranged for initiating operation upon selection by a customer for vending an article into a vend space through which the article falls into a customer-accessible hopper, a method comprising: providing an article sensing subsystem arranged athwart said vend space, said article sensing subsystem comprising: (a1) a first emitter/detector array comprising at least one emitter and a plurality of detectors, and (a2) a second emitter/detector array comprising at least one emitter and a plurality of detectors, positioning and arranging said first and second emitter/detector arrays so that electromagnetic radiation emitted by said at least one emitter of said first array may be detected by at least some of said plurality of detectors of said second array, and so that electromagnetic radiation emitted by said at least one emitter of said second array may be detected by at least some of said plurality of detectors of said first array, and so that articles falling through the vend space will interrupt electromagnetic radiation between at least one emitter and at least one detector.
 7. A light curtain device for use in a vending machine which has at least one mechanism arranged for initiating operation upon selection by a customer for vending an article into a vend space through which the article falls into a customer-accessible hopper, said light curtain device comprising: first and second emitter/detector arrays, each comprising at least one emitter and a plurality of detectors, said arrays being positionable and arrangeable within said vending machine so that electromagnetic radiation emitted by said at least one emitter of said first array may be detected by at least some of said plurality of detectors of said second array, and so that electromagnetic radiation emitted by said at least one emitter of said second array may be detected by at least some of said plurality of detectors of said first array, and so that articles falling through the vend space of the vending machine will interrupt electromagnetic radiation between at least one emitter and at least one detector.
 8. A light curtain device as in claim 7 wherein each of said emitter/detector arrays has an emitter on an end thereof.
 9. A light curtain device as in claim 7 wherein each of said emitter/detector arrays has two emitters on an end thereof.
 10. A light curtain device as in claim 7 wherein each of said emitter/detector arrays has between twelve and fourteen detectors, inclusive and has one emitter on an end thereof.
 11. A light curtain device as in claim 10 wherein the emitters are approximately equally spaced.
 12. A light curtain device as in claim 7 wherein, for each of said emitter/detector arrays, said at least one emitter and said plurality of detectors are positioned in a straight row.
 13. A light curtain device as in claim 7 wherein first and second emitter/detector arrays are identical.
 14. A light curtain device for use in a vending machine which has at least one mechanism arranged for initiating operation upon selection by a customer for vending an article into a vend space through which the article falls into a customer-accessible hopper, said light curtain comprising: at least one detector; and at least one emitter mounted opposite said at least one detector and on a movable mechanism.
 15. A light curtain device as in claim 12 wherein: each said at least one detector is arranged on a first oscillating or rotating wheel, and wherein the movable mechanism comprises a second oscillating or rotating wheel.
 16. A light curtain device as in claim 12 wherein: each said at least one detector is arranged on a first oscillating or rotating pendulum arm, and wherein the movable mechanism comprises a second oscillating or rotating pendulum arm.
 17. A light curtain device for use in a vending machine which has at least one mechanism arranged for initiating operation upon selection by a customer for vending an article into a vend space through which the article falls into a customer-accessible hopper, said light curtain comprising: at least one emitter; and at least one detector mounted opposite said at least one detector and on a movable mechanism.
 18. A light curtain device as in claim 17 wherein: each said at least one emitter is arranged in a fixed location, and wherein the movable mechanism comprises an oscillating pendulum arm.
 19. A light curtain device as in claim 17 wherein: each said at least one emitter is arranged in a fixed location, and wherein the movable mechanism comprises an oscillating or rotating wheel. 